A storage device is provided which shares a host memory with a host. The storage device includes an interface that exchanges data with the host and implements a protocol to use a partial area of the host memory as a buffer of the storage device. A storage controller of the storage device monitors deterioration information of a first area of the buffer and transmits a corruption prediction notification associated with the first area to the host based on a result of the monitoring.

The present disclosure generally relates to methods of operating storage devices. The storage device comprises a controller comprising first random access memory (RAM1), second random access memory (RAM2), and a storage unit divided into a plurality of zones. A first command to write data to a first zone is received, first XOR data is generated in the RAM1, and the data of the first command is written to the first zone. When a second command to write data to a second zone is received, the generated first XOR data is copied from the RAM1 to the RAM2, and second XOR data for the second zone is copied from the RAM2 to the RAM1. The second XOR data is updated with the second command, and the data of the second command is written to the second zone. The updated second XOR data is copied from the RAM1 to the RAM2.

A memory expansion device operable with a host computer system (host) comprises a non-volatile memory (NVM) subsystem, cache memory, and control logic configurable to receive a submission from the host including a read command and specifying a payload in the NVM subsystem and demand data in the payload. The control logic is configured to request ownership of a set of cache lines corresponding to the payload, to indicate completion of the submission after acquiring ownership of the cache lines, and to load the payload to the cache memory. The set of cache lines correspond to a set of cache lines in a coherent destination memory space accessible by the host. The control logic is further configured to, after indicating completion of the submission and in response to a request from the host to read demand data in the payload, return the demand data after determining that the demand data is in the cache memory.

An interface device between a plurality of memory devices and a memory controller includes processing circuitry configured to provide a plurality of controller channels for communicating with the memory controller, to provide a plurality of memory channels for communicating with the plurality of memory devices, and to connect each of the plurality of controller channels to at least one of the plurality of memory channels in a first mode and disconnect the plurality of controller channels from the plurality of memory channels in a second mode.

An improved data access method for direct memory access (DMA), comprising: allocating m DMA hardware descriptors, and n data buffer units from a data buffer to the controller; constructing software descriptors of the buffer into a two-dimensional array with each row directing to one buffer unit, wherein the value of a first subscript of each array item ranges between 0 and n−1, and the value of a second subscript ranges between 0 and 1; respectively storing a virtual and physical address of the same buffer unit in a column of the two-dimensional array of the corresponding software descriptor; creating an index to establish a directional relationship between the buffer units and the software descriptors, the index comprising an idle index and a scheduling index; and implementing the hardware and software descriptors access by the CPU and DMA to a memory in a data transfer process of the high-speed interface.

A data transmission system and an operation method thereof are provided. The data transmission system includes a host, a first device and a second device. The host is configured to set a voltage base of a transmission signal, and configured to pull down or up the transmission signal based on the voltage base of the transmission signal to form a plurality of glitches. The first device is connected to the host to receive the transmission signal. The first device obtains a digital content of the transmission signal according to the glitches, if the voltage base of the transmission signal is set as a first base. The second device is connected to the host to receive the transmission signal. The second device obtains the digital content of the transmission signal according to the glitches, if the voltage base of the transmission signal is set as a second base.

In a memory subsystem, a physical interface (PHY) has an unmatched architecture. To compensate for the unmatched architecture, the PHY has variable delay compensation to adjust for propagation mismatch of analog signals in the data (DQ) path and data strobe (DQS) path of the PHY. The variable delay compensation can be provided by adjusting the operation of a digital component of the PHY to introduce the delay compensation.

In one embodiment, one or more control units may store a position tracker associated with a first window of memory blocks and allow a first processing unit to write data within the first window. The control units may receive, from a second processing unit, a request for reading data with a memory-reading address, compare the memory-reading address to a first starting address of the first window, and prevent the second processing unit from reading the data when the memory-reading address is greater than or equal to the first starting address of the first window. The control units may store, when the data writing process is complete, an updated position tracker of a second window of memory blocks and allow the second processing unit to read the data based on a determination that the memory-reading address is less than a second starting address of the second window.

Apparatus, systems and methods for implementing delayed decompression schemes. As a burst of packets comprising compressed packets and uncompressed packets are received over an interconnect link, they are buffered in a receive buffer without decompression. Subsequently, the packets are forwarded from the receive buffer to a consumer such as processor core, with the compressed packets being decompressed prior to reaching the processor core. Under a first delayed decompression approach, packets are decompressed when they are read from the receive buffer in conjunction with forwarding the uncompressed packet (or uncompressed data contained therein) to the consumer. Under a second delayed decompression scheme, the packets are read from the receive buffer and forwarded to a decompressor using a first datapath width matching the width of the packets, decompressed, and then forwarded to the consumer using a second datapath width matching the width of the uncompressed data.

A memory module includes a substrate, plural memory devices, and a buffer. The plural memory devices are organized into at least one rank, each memory device having plural banks. The buffer includes a primary interface for communicating with a memory controller and a secondary interface coupled to the plural memory devices. For each bank of each rank of memory devices, the buffer includes data buffer circuitry and address buffer circuitry. The data buffer circuitry includes first storage to store write data transferred during a bank cycle interval (tRR). The address buffer circuitry includes second storage to store address information corresponding to the data stored in the first storage.